This application claims the benefits of the Taiwan Patent Application Serial No. 099223975 filed on Dec. 10, 2010, the subject matter of which is incorporated herein by reference.
1. Field of the Invention
The present invention relates to a juxtaposed type electrical connector assembly, more particularly to one juxtaposed type electrical connector assembly including a plurality of juxtaposed casings and a positioning bottom plate for supporting the juxtaposed casings thereon in such a manner that the positioning bottom plate can absorb the accumulated tolerance caused due to juxtaposed connection among the casings.
2. Description of the Prior Art
A conventional electrical connector assembly generally includes a casing structure defining a plurality of plug chambers for receiving respectively several pieces of plug units provided a cable-holding member or an optical fiber switch. The casing structure presently available is made mostly from plastic material, and has a fixed number of chambers such that during manufacture of the conventional electrical connector assembly, several different pieces of molds are required in order to form the plug chambers with different sizes, hence causing the unnecessary manufacturing cost.
To overcome the aforesaid disadvantages encountered during manufacturing of the conventional electrical connector assembly, the ROC (Taiwan) patent publication number M354926 has disclosed a juxtaposed type electrical connector assembly, which includes a plurality of juxtaposed casings, wherein an adjacent pair of the juxtaposed casings share a common partition to form two plug chambers of different sizes. Hence two different plug chambers can be formed to receive different plug units therein and thus economizing the construction material and the expense for constructing new molds.
The auxiliary casing PA20 is juxtaposed and connected to the basic casing PA10 via the first and second engaging structures PA12, PA22. The other auxiliary casing PA20a is juxtaposed and connected to the auxiliary casing PA20 via the second and third engaging structures PA22a, PA 23, hence the latter assembly thereof is connected to the basic casing PA10, thereby forming the conventional electrical connector assembly PA100.
After the conventional electrical connector assembly is assembled as stated in the aforesaid manner, the fixing pins PA11, PA21, PA21a of the basic casing PA10 and the auxiliary casings PA20, PA20a are inserted into a printed circuit board 200, thereby mounting the conventional electrical connector assembly securely on the printed circuit board 200.
Whether an automatic or manual mounting process is applied for mounting the conventional electrical connector assembly on the printed circuit board 200 securely, it is relatively difficult to avoid the problem of displacement phenomenon. This situation is aggravated since the conventional electrical connector assembly PA100 is formed by several pieces of the auxiliary casings PA20, PA20a assembled to one another in the juxtaposed connection, hence resulting in accumulated tolerance thereamong. In addition, the printed circuit board generally has a design tolerance after production, which, in turn, increases the amount of accumulated tolerance when the conventional electrical connector assembly is mounted on the printed circuit board 200. Since all the electronic devices available in the market are aimed to be produced in compact size, the casings as well as the circuit paths in the printed circuit board are required to be designed in compact manner or densely located manner. Hence the presence of accumulated tolerance during mounting the conventional assembly on the printed circuit board brings undesired effects thereof.
In the prior art technique, the conventional electrical connector assembly has a greater accumulated tolerance. However, the electrical connector assembly produced according to the present invention can absorb the accumulated tolerance, thereby reducing the displacement phenomenon during the mounting operation of the same onto the printed circuit board.
The object of the present invention is to provide an electrical connector assembly, which can overcome the disadvantages of the prior art ones. The electrical connector assembly of the present invention includes a plurality of juxtaposed auxiliary casings and a positioning bottom plate. Each of the auxiliary casings includes a top plate, a side wall extending downwardly from a lateral side of the top plate along a mounting direction and having a bottom end, and at least one fixing pin projecting downward from the bottom end of the side wall along the mounting direction. The positioning bottom plate is disposed at a level below the juxtaposed auxiliary casings, and is formed with several rows of fixing channel such that an adjacent pair of the rows is spaced apart from each other by a standard distance. Each row of the fixing channels is aligned with the fixing pin of a respective one of the auxiliary casings.
The auxiliary casings are juxtaposed and connected to one another along an assembling direction transverse to the mounting direction. When the juxtaposed auxiliary casings are brought along the mounting direction to fix securely on a printed circuit board supporting the positioning bottom plate from underneath, the fixing pins of the auxiliary casings respectively extend through the fixing channels in the positioning bottom plate in such a manner that the positioning bottom plate absorbs an accumulated tolerance caused due to the juxtaposed connection among the auxiliary casings along the assembling direction.
The electrical connector assembly of the present invention further includes a basic casing having a top plate, two side walls extending respectively and downwardly from two lateral sides of the top plate along the mounting direction toward the printed circuit board, and a plurality of basic engaging structures mounted to the top plate at the lateral sides thereof. Each of the basic engaging structures is preferably in the form of an engaging loop.
Each of the auxiliary casings further includes a plurality of first engaging structures and a plurality of second engaging structures, which are mounted respectively to the lateral sides of the top plate of a respective one of the auxiliary casings. Preferably each of the first engaging structure is a fastener hook while each of the second engaging structure is an engaging loop for receiving the fastener hook therein. Under this condition, the first engaging structures of one of the auxiliary casings adjacent to the basic casing are engaged respectively with the basic engaging structures of the basic casing, thereby juxtaposing and connecting the one of the auxiliary casings and the basic casing along the assembling direction.
In one embodiment, the electrical connector assembly of the present invention further includes a plurality of plug units respectively received within the basic casing and the plurality of auxiliary casings and are further coupled electrically to one another in series along the assembling direction.
In the conventional electrical connector assembly, after the basic casing and the auxiliary casings are coupled interactively at the top plates thereof and when inserting the fixing pins of these casings relative to the printed circuit board, the displacement phenomenon is resulted easily, hence a predetermined amount of accumulated tolerance is also resulted. However, in the electrical connector assembly of the present invention, owing to the presence of the positioning bottom plate and since two adjacent rows of the positioning channel in the positioning bottom plate are spaced apart from each other by a standard distance, the absorb amount of the accumulated tolerance during the mounting operation of the electrical connector assembly of the present invention onto the printed circuit plate is increased, which, in turn, reduces the accumulated tolerance caused due to juxtaposed connection of the basic and auxiliary casings in series along the assembling direction.
Other features and advantages of this invention will become more apparent in the following detailed description of the preferred embodiment of this invention, with reference to the accompanying drawings, in which:
The present invention relates to a juxtaposed type electrical connector assembly, more particularly to one juxtaposed type electrical connector assembly, which includes a plurality of juxtaposed connectors in the form of casings and a positioning bottom plate for supporting the juxtaposed casings from underneath such that the positioning bottom plate can absorb the accumulated tolerance caused due to juxtaposed connection among the casings. A preferred embodiment of the juxtaposed type electrical connector assembly is disclosed in the following paragraphs for better understanding of the present invention. However, the scope of the present invention should not be limited only to the structure of the disclosed embodiment.
Referring to
The basic casing 10 is preferably made from metal and includes a top plate 11, two side walls 12 extending respectively and downwardly from two lateral sides of the top plate 11 along a mounting direction (I1) toward the printed circuit board, a plurality of basic engaging structures 14 mounted to the top plate 11 at the lateral sides thereof and a plurality of fixing pins 13 projecting downward from bottom ends of the side walls 12 along the mounting direction (I1). Preferably, each basic engaging structure 14 is in the form of an engaging loop.
The auxiliary casings 20, 20a are juxtaposed and connected to one another, and extend along an assembling direction (I2) transverse perpendicularly to the mounting direction (I1). One of the auxiliary casings 20, 20a is juxtaposed to and assembled to the basic casing 10 along the mounting direction (I1). The auxiliary casing 20 is preferably made from metal, and includes a top plate 21, a side wall 22 that extends downwardly from a lateral side of the top plate 21 along the mounting direction (I1) and that has a bottom end, and a plurality of fixing pins 23 projecting downward from the bottom end of the side wall 22 along the mounting direction (I1).
The auxiliary casing 20 further includes a plurality of first engaging structures 24 and a plurality of second engaging structures 25 mounted respectively to two lateral sides of the top plate 21. In this embodiment, each of the first engaging structures 24 is a fastener hook while each of the second engaging structures 25 is an engaging loop for receiving the respective fastener hook therein. In this regard, the first engaging structures 24 of the auxiliary casing 20 adjacent to the basic casing 10 are engaged respectively with the basic engaging structures 14 of the basic casing 10, thereby juxtaposing and connecting the auxiliary casing 20 to the basic casing 10 in series along the assembling direction (I2).
In the same manner, the first engaging structures 24a of the auxiliary casing 20a are respectively engaged to the second engaging structures 25 of the auxiliary casing 20, thereby juxtaposing and connecting the auxiliary casing 20a to the auxiliary casing 20 along the assembling direction (I2). Under this condition, several pieces of plug units 40 are respectively received within the basic casing 10 and the plurality of auxiliary casings 20, 20a due to the reason that each casing serves as an electrical connector. In this embodiment, the pieces of plug units cooperatively form a SFP module (Small Form-factor Pluggable transceiver).
Referring to
After assembling the basic casing 10 and the auxiliary casings 20, 20a in series along the assembly direction (I2) as described above, and when it is desired to mount the assembly thereof onto a printed circuit board 200 which is disposed below and supporting the positioning bottom plate 30 from underneath, the assembly is brought downward along the mounting direction (I1) to fix securely on the printed circuit board 200. Under this condition, the fixing pins 13, 23 of the basic casing 10 and the auxiliary casings 20,20a respectively extend through the fixing channels 31 in the positioning bottom plate 30 in such a manner that the positioning bottom plate 30 absorbs an accumulated tolerance caused due to the juxtaposed connection among the basic casing 10 and the auxiliary casings 20, 20a along the assembling direction. In other words, the displacement phenomenon during mounting operation of the electrical connector assembly 100 onto the printed circuit board 200 is reduced considerably, hence upgrading the mounting precision of the electrical connector assembly 100 of the present invention relative to the printed circuit board 200.
In the conventional electrical connector assembly, after the basic casing and the auxiliary casings are coupled interactively at the top plates thereof and when inserting the fixing pins of these casings relative to the printed circuit board, the displacement phenomenon is resulted, hence a predetermined amount of accumulated tolerance is also resulted. However, in the electrical connector assembly of the present invention, owing to the presence of the positioning bottom plate 30 and since two adjacent rows of the positioning channel 31 are spaced apart from each other by a standard distance (d), the absorb amount of the accumulated tolerance during the mounting operation of the electrical connector assembly 100 of the present invention onto the printed circuit plate 200 is increased, which, in turn, reducing the accumulated tolerance caused due to juxtaposed connection of the basic and auxiliary casings 10, 20, 20a in series.
While the invention has been described in connection with what is considered the most practical and preferred embodiments, it is understood that this invention is not limited to the disclosed embodiments but is intended to cover various arrangements included within the spirit and scope of the broadest interpretation so as to encompass all such modifications and equivalent arrangements.
Number | Date | Country | Kind |
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99223975 U | Dec 2010 | TW | national |
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Number | Date | Country | |
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20120145452 A1 | Jun 2012 | US |